Error Analysis of an Unfitted HDG Method for a Class of Non-linear Elliptic Problems

Nestor Sánchez; Tonatiuh Sánchez-Vizuet; Manuel Solano

doi:10.1007/s10915-022-01767-1

Error Analysis of an Unfitted HDG Method for a Class of Non-linear Elliptic Problems

Nestor Sánchez, Tonatiuh Sánchez-Vizuet, Manuel Solano

Mathematics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We study Hibridizable Discontinuous Galerkin (HDG) discretizations for a class of non-linear interior elliptic boundary value problems posed in curved domains where both the source term and the diffusion coefficient are non-linear. We consider the cases where the non-linear diffusion coefficient depends on the solution and on the gradient of the solution. To sidestep the need for curved elements, the discrete solution is computed on a polygonal subdomain that is not assumed to interpolate the true boundary, giving rise to an unfitted computational mesh. We show that, under mild assumptions on the source term and the computational domain, the discrete systems are well posed. Furthermore, we provide a priori error estimates showing that the discrete solution will have optimal order of convergence as long as the distance between the curved boundary and the computational boundary remains of the same order of magnitude as the mesh parameter.

Original language	English (US)
Article number	92
Journal	Journal of Scientific Computing
Volume	90
Issue number	3
DOIs	https://doi.org/10.1007/s10915-022-01767-1
State	Published - Mar 2022

Keywords

Curved boundary
Hybridizable discontinuous Galerkin
Non-linear boundary value problems
Transfer paths
Unfitted mesh

ASJC Scopus subject areas

Software
Theoretical Computer Science
Numerical Analysis
Engineering(all)
Computational Theory and Mathematics
Computational Mathematics
Applied Mathematics

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title = "Error Analysis of an Unfitted HDG Method for a Class of Non-linear Elliptic Problems",

abstract = "We study Hibridizable Discontinuous Galerkin (HDG) discretizations for a class of non-linear interior elliptic boundary value problems posed in curved domains where both the source term and the diffusion coefficient are non-linear. We consider the cases where the non-linear diffusion coefficient depends on the solution and on the gradient of the solution. To sidestep the need for curved elements, the discrete solution is computed on a polygonal subdomain that is not assumed to interpolate the true boundary, giving rise to an unfitted computational mesh. We show that, under mild assumptions on the source term and the computational domain, the discrete systems are well posed. Furthermore, we provide a priori error estimates showing that the discrete solution will have optimal order of convergence as long as the distance between the curved boundary and the computational boundary remains of the same order of magnitude as the mesh parameter.",

keywords = "Curved boundary, Hybridizable discontinuous Galerkin, Non-linear boundary value problems, Transfer paths, Unfitted mesh",

author = "Nestor S{\'a}nchez and Tonatiuh S{\'a}nchez-Vizuet and Manuel Solano",

note = "Funding Information: The authors have no relevant financial or non-financial interests to disclose. All authors have contributed equally to the article and the order of authorship has been determined alphabetically. Nestor S{\'a}nchez is supported by the Scholarship Program of CONICYT-Chile. Manuel E. Solano was partially funded by CONICYT–Chile through FONDECYT project No. 1200569 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cient{\'i}ficos y Tecnol{\'o}gicos de Excelencia con Financiamiento Basal. Tonatiuh S{\'a}nchez–Vizuet was partially supported by the National Science Foundation throught the grant NSF-DMS-2137305 “LEAPS-MPS: Hybridizable discontinuous Galerkin methods for non-linear integro-differential boundary value problems in magnetic plasma confinement”. Funding Information: The authors have no relevant financial or non-financial interests to disclose. All authors have contributed equally to the article and the order of authorship has been determined alphabetically. Nestor S?nchez is supported by the Scholarship Program of CONICYT-Chile. Manuel E. Solano was partially funded by CONICYT?Chile through FONDECYT project No. 1200569 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cient?ficos y Tecnol?gicos de Excelencia con Financiamiento Basal. Tonatiuh S?nchez?Vizuet was partially supported by the National Science Foundation throught the grant NSF-DMS-2137305 ?LEAPS-MPS: Hybridizable discontinuous Galerkin methods for non-linear integro-differential boundary value problems in magnetic plasma confinement?. Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.",

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doi = "10.1007/s10915-022-01767-1",

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N1 - Funding Information: The authors have no relevant financial or non-financial interests to disclose. All authors have contributed equally to the article and the order of authorship has been determined alphabetically. Nestor Sánchez is supported by the Scholarship Program of CONICYT-Chile. Manuel E. Solano was partially funded by CONICYT–Chile through FONDECYT project No. 1200569 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Científicos y Tecnológicos de Excelencia con Financiamiento Basal. Tonatiuh Sánchez–Vizuet was partially supported by the National Science Foundation throught the grant NSF-DMS-2137305 “LEAPS-MPS: Hybridizable discontinuous Galerkin methods for non-linear integro-differential boundary value problems in magnetic plasma confinement”. Funding Information: The authors have no relevant financial or non-financial interests to disclose. All authors have contributed equally to the article and the order of authorship has been determined alphabetically. Nestor S?nchez is supported by the Scholarship Program of CONICYT-Chile. Manuel E. Solano was partially funded by CONICYT?Chile through FONDECYT project No. 1200569 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cient?ficos y Tecnol?gicos de Excelencia con Financiamiento Basal. Tonatiuh S?nchez?Vizuet was partially supported by the National Science Foundation throught the grant NSF-DMS-2137305 ?LEAPS-MPS: Hybridizable discontinuous Galerkin methods for non-linear integro-differential boundary value problems in magnetic plasma confinement?. Publisher Copyright: © 2022, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.

PY - 2022/3

Y1 - 2022/3

N2 - We study Hibridizable Discontinuous Galerkin (HDG) discretizations for a class of non-linear interior elliptic boundary value problems posed in curved domains where both the source term and the diffusion coefficient are non-linear. We consider the cases where the non-linear diffusion coefficient depends on the solution and on the gradient of the solution. To sidestep the need for curved elements, the discrete solution is computed on a polygonal subdomain that is not assumed to interpolate the true boundary, giving rise to an unfitted computational mesh. We show that, under mild assumptions on the source term and the computational domain, the discrete systems are well posed. Furthermore, we provide a priori error estimates showing that the discrete solution will have optimal order of convergence as long as the distance between the curved boundary and the computational boundary remains of the same order of magnitude as the mesh parameter.

AB - We study Hibridizable Discontinuous Galerkin (HDG) discretizations for a class of non-linear interior elliptic boundary value problems posed in curved domains where both the source term and the diffusion coefficient are non-linear. We consider the cases where the non-linear diffusion coefficient depends on the solution and on the gradient of the solution. To sidestep the need for curved elements, the discrete solution is computed on a polygonal subdomain that is not assumed to interpolate the true boundary, giving rise to an unfitted computational mesh. We show that, under mild assumptions on the source term and the computational domain, the discrete systems are well posed. Furthermore, we provide a priori error estimates showing that the discrete solution will have optimal order of convergence as long as the distance between the curved boundary and the computational boundary remains of the same order of magnitude as the mesh parameter.

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Error Analysis of an Unfitted HDG Method for a Class of Non-linear Elliptic Problems

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Keywords

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